DE102011110682A1 - Junction box for a solar panel with a protection circuit - Google Patents

Abstract

The invention relates to a connection box for a solar panel with a protective circuit, which defines an operating state and a protective state. The protection circuit comprises a short-circuit switch between the output-side connection elements of the first and second external connection line and a disconnector between the short-circuit switch and one of the poles of the solar panel, wherein in the protective state of the short-circuit switch short-circuits the output-side connection elements of the first and second external connection line and the circuit breaker short-circuit at least one side separates from the solar panel.

Description

Field of the invention

The invention relates to a junction box for a solar panel with a protection circuit, in particular for selectively disconnecting one or more solar panels of a solar generator from the external connection lines.

Background of the invention

Solar panels typically include a junction box, sometimes referred to as a PV (photovoltaic) junction box, (PV) junction box, or (PV) junction box. This junction box has a typically flat dielectric housing and is mounted on the solar-remote rear side of the solar panel, z. B. glued. The solar panels have live conductors, typically in the form of thin conductor strips, the so-called ribbons, which emerge from the back of the solar panels and form the electrical poles of the solar panel, d. H. between which the voltage generated by the solar panel is applied. A solar panel typically has a plurality of solar cells connected in series and / or in parallel in the solar panel. Possibly. are still one or more intermediate taps between the solar cells or groups of solar cells of the solar panel led out of this and contacted in the junction box. The junction box for the solar panel usually contains inside input side connection elements, eg. B. spring terminals with which the projecting through the bottom of the junction box inside the junction box conductor strip of the plus and the negative terminal of the solar panel are connected or contacted and a bypass diode for the solar panel and possibly other connection elements and other bypass diodes solar panels with one or more intermediate taps.

The junction box also has output-side connection elements, for. B. in the form of spring-loaded terminals or connectors for connecting the external leads, so that the first and second external connection line can be electrically connected by means of the output-side connection elements and hereby connected within the junction box input-side connection elements with the positive pole or the negative terminal of the solar panel to wire the solar panels.

Examples of such junction boxes for solar panels are in the DE 10 2007 037 130 and the DE 10 2007 042 547 described.

A solar generator typically consists of a plurality of solar panels, which in turn are connected in series to strings (so-called strings) in order to achieve a solar generator DC voltage of currently typically up to 1000 V. Further, depending on the number of solar panels connected together and their individual voltage in turn, if necessary, more of the strands are connected in parallel. Due to the high voltage in the DC part of the solar system and the occurring currents that may be in the ampere range, there is a fault in such. As in a fire, the acute danger that rescue workers could be exposed to life-threatening tensions. In particular, the fire department would run when deleting a burning roof truss with a solar system risk to be exposed to life-threatening electrical voltages on the fire water. This danger exists in particular during the day, but even at night, even the existing low light can lead to dangerous voltages in larger systems. However, such dangers are not only in case of fire, but may also exist in other exceptional accidents or accidents, eg. As in storm damage or motor vehicle collisions with free-field systems, to name just a few examples without claiming to be complete.

Although a solar system typically has a main circuit breaker in the so-called generator junction box, but can be hereby, z. B. in case of damage from fire, water, hail, etc. on the solar panels or on the connecting lines not unlock the area in front of the generator junction box. Furthermore, a selective activation of individual solar panels is also not possible.

In addition, solar panels generate voltage at all times when they are illuminated, which may already be the case when installing the solar junction boxes on the solar panel, storage, transport and in particular when mounting the solar panels at the destination. Therefore, it may, for. B. come during installation of the solar panels and when connecting the leads with appropriate lighting to high voltages that require safe handling and a special contact protection. Even a single solar panel can already generate a voltage due to a series connection of several solar cells in the solar panel, which requires safety precautions. Therefore, typically touch-protected connector, z. B. from the SUNCLIX ^® system used by the applicant, which already ensure a high level of security. However, it may still be desirable to switch the solar generator as far as possible without voltage to increase safety and before Main disconnect switch, especially directly on the solar panels.

From the DE 10 2009 024 516 A1 a safety device for a junction box for the electrical connection of a solar panel is known, which produces an electrically conductive cross-connection between the connection elements in the junction box, so that in the active state, the output voltage is reduced to zero.

If the cross connection is made, however, there is a loss of performance at the safety device, which may possibly lead to undesirable heating. Permanently staying in this condition may result in damage to the safety equipment or solar panels.

Furthermore, this safety device is especially for shorting in case of fire, d. H. a fault during operation meant. The bringing of the safety device into the state in which the output voltage is reduced to zero requires an active control intervention for this purpose. In case of an accident, such as a fire, the safety device may at the time of the desired activation, z. B. by the fire department, even already be damaged or destroyed, so that the safety device at this time may not be activated and therefore the desired security functionality is no longer effective.

Thus, although there are already various security measures for photovoltaic generators, nevertheless they can be improved further.

General description of the invention

The invention therefore has the task of providing a junction box for a solar panel with a protective circuit or a protective circuit, which ensures a high degree of safety in case of failure.

A further object of the invention is to provide a junction box for a solar panel with a protective circuit or a protective circuit which can remain in the protective state over a long period of time and a high degree of safety even during storage, transport and assembly, as well ensures a comfortable installation.

Yet another object of the invention is to provide a junction box for a solar panel with a protective circuit or a protective circuit, which automatically goes into the protective state in a fault, possibly even in partial destruction, and in which the junction box in the protective state still certain functions can provide.

The object of the invention is solved by the subject matter of the independent claims. Advantageous developments of the invention are defined in the subclaims.

According to the invention, a junction box for a solar panel is provided for the electrical connection of external connection lines to a solar panel. The junction box comprises a mountable on the solar panel junction box, which in particular has a auflegbare on the solar panel underside with openings for inserting the emerging from the solar panel live conductor in the junction box. These live conductors of the positive pole and the negative pole of the solar panel are usually designed as thin conductor strips, so-called ribbons. At the bottom of the hat-shaped junction box has z. B. a peripheral adhesive edge, with which the junction box is glued to the solar-remote rear side of the solar panel. In the junction box housing coming from the solar panel and extending into the junction box conductor strips are by means of input-side connection elements, for. B. spring terminals electrically connected. Thus, the junction box has at least one input-side electrical connection element for the positive pole conductor strip and an input-side electrical connection element for the negative pole conductor strip.

The junction box further comprises at least a first and second output-side connection element for connecting a first and second external connection line, for. As the two strand cable, with which the solar panel connected to other solar panels together, z. B. is connected in series with the respective adjacent solar panels. The connection elements for the external connection cable can be z. B. may be formed as terminals, by means of which the introduced into the junction box end of the respective stranded cable is contacted or the junction box itself already has connectors for connecting the respective stranded cable.

In the junction box also an electrical or electronic protection circuit is installed, which defines an operating condition and a protective state. In the operating state, the respective solar panel is connected to the current-decreasing devices, ie in a grid-connected solar system to the power grid and feeds its electrical power into the power grid. Accordingly, in the operating state, the first external connection line is electrically connected to the live conductor of the positive pole of the solar panel and the second external connection line to the live conductor of the negative pole of the solar panel, so that the electric power generated by the solar panel via the first and second external connection line in the power grid can be fed.

The protection circuit comprises a short-circuit switch between the output-side connection elements of the first and second external connection line and an isolation switch between the short-circuit switch and one of the two poles of the solar panel. The short-circuit switch is opened in the operating state, so that the electric power of the solar panel can be fed into the grid and in the protection state, the output-side connection elements of the first and second external connection line are short-circuited within the junction box. This already causes this solar panel can no longer deliver power over the string line. The circuit breaker is now connected in series between the positive pole conductor of the solar panel or the negative pole conductor of the solar panel and the shorting switch. In the operating state, therefore, the short-circuiting switch is opened and the disconnector is closed to direct and feed the electric current of the solar panel to the output-side terminal elements. In the protective state, however, the circuit breaker is open to disconnect the closed short-circuit switch at least one side of the poles of the solar panel. Thus, in the protection state, the external connection lines are switched off with respect to this solar panel, to the effect that it is bridged on the one hand within the string line by means of the short circuit switch and on the other hand additionally separated at least one side of the string lines, so that the solar panel is not short-circuited despite closed short-circuit switch itself ,

This has several advantages. First, the short-circuit switch is not burdened by the power loss of the associated solar panel, but acts only as a low-impedance bypass of this solar panel within the string line. As a result, the protective circuit can remain in the protective state for practically any length of time, even without significant heating, even when the solar panel is illuminated. On the other hand, the associated solar panel is not short-circuited in spite of this short-circuit bypass, so that the electrical power of the solar panel is not fed into the string line, but is still available within the junction box. Thus, electrical or electronic devices in the junction box of the associated solar panel can still be supplied with electrical energy, although the protection circuit is in the protection state and the output side of the junction box is shorted.

The short-circuit switch is seen in the junction box of the poles of the solar panel, in particular directly in front of the output-side connection elements of the first and second external connection line, z. B. the terminals for the stripped ends of the stranded line within the junction box or the integrated connector for the stranded line arranged. The circuit breaker is connected in the junction box serially directly between the input-side connection element of the live conductor of the positive pole of the solar panel or the input-side connection element of the live conductor of the negative pole of the solar panel and one of the terminals of the shorting switch.

The junction box preferably has a conventional bypass circuit to compensate for shadowing, z. B. a bypass diode on. In this case, the circuit breaker is connected in series with the shading compensation bypass circuit, and the shorting switch is connected in parallel with the shading compensation bypass circuit. The bypass circuit for compensation of shading is seen from the poles of the solar panel from the switch and the shorting switch is connected so that the bypass circuit to compensate for shadowing remains connected in the protective state with the solar panel and is in operation. This can be particularly advantageous for solar panels with intermediate taps and multiple bypass circuits per solar panel or junction box.

Solar panels typically have a plurality of solar cells, which are connected in series and / or in parallel within the solar panel. Frequently, the solar panels then have intermediate taps, at which the electrical power is tapped within the solar cells connected in series in the solar panel and / or in parallel to groups. These groups can then be contacted separately by means of the junction box. For this purpose, the junction box in the junction box housing further input-side connection elements for connecting coming from the solar panel conductor strips of Zwischenabgriffe and several bypass circuits to compensate for shadowing between the input-side connection elements for the Leiterbändchen the positive pole, the Zwischenabgriffe and the negative pole of the solar panel. Accordingly, the bypass circuits are in each case connected in parallel to the sections of the respective solar panel which are contacted separately with the junction box, if the junction box is located on the Solar panel is mounted. In this case, the short-circuit switch is connected in parallel with all bypass circuits to compensate shading and all groups of solar cells or separately contacted sections of the solar panel and the circuit breaker is in series between the short-circuit switch and all bypass circuits to compensate for shadowing and all separately contacted sections of the Solar panels switched. Thus, in the protective state of the short-circuiting switch by means of the release switch disconnected from all separately contacted sections of the solar panel and all bypass circuits to compensate for shadowing.

In particular, the protection circuit or the short-circuit switch and the circuit breaker are installed in the junction box from the poles of the solar panel from any outside of the junction box housing releasable connectors installed. This can ensure that any detachable cable connection outside the junction box housing can be switched power-free, whereby a high safety standard is achieved.

According to one embodiment of the invention, the junction box comprises a control device which controls the switching of the protection circuit, more precisely the short-circuit switch and the circuit breaker, from the protection state into the operating state. The control device is seen from the poles of the solar panel arranged in front of the circuit breaker and can thus be supplied not only in the operating condition, but also in the protective state of the associated solar panel with electrical energy, since the control device in the protective state by means of the release switch at least one side of the Short-circuit switch is disconnected, but remains connected to the solar cells. Thus, the control means for controlling the switches of the protection circuit can be supplied with electric power not only in the operation state but also in the protection state. Furthermore, the protection circuit is in particular designed to be reversible, so that it can be switched as often as desired from the operating state to the protection state and back again. Therefore, the protection circuit disclosed here can not only once, z. B. in the event of fire in the protective stand, but without manual intervention in the junction box reversible z. B. also during assembly and installation as well as maintenance. Another advantage is that the solar panels can be switched individually in the protection state, d. H. can be disconnected individually from the strand.

In a simple embodiment, the protection circuit consists only of the control device, a short-circuit switch and an unlock switch. Suitably, the short-circuit switch and / or the disconnector are designed as mechanical switches, electromechanical switches or semiconductor switches.

In a preferred embodiment, the short-circuiting switch is designed as an opener, which is closed in the idle state. The circuit breaker is designed as a normally open and open at rest. This achieves in an advantageous manner that the short-circuit switch and the circuit breaker automatically automatically switch to the idle state when they are no longer supplied with electrical energy from the solar panel. Therefore, the protection circuit, even in absolute darkness, in an interruption of the electrical connection to the associated solar panel, z. B. in a faulty contact on the conductor strip or in a late fire, when the solar module is already destroyed, still switching from the operating state to the protective state. Further, the protection circuit automatically switches to the protection state when the control device is defective. The controller is preferably arranged such that, once the protection circuit is in the protection state, it remains in the protection state until it is activated by the control device, i. H. is actively switched from the idle protection state into the operating state, even if the associated solar panel should provide electrical power again. This is z. B. designed as an opener or normally closed relay for the short-circuit switch and a trained as normally open or normally open relay for the circuit breaker. However, a protective circuit in which the protective state is formed as a sleep state can also be realized with a self-conducting MOS-FET (depletion type) and a self-blocking MOS-FET (enhancement type) as a short-circuit switch or disconnector.

The activation of the protective state in the operating state is preferably carried out remotely from outside the junction box, z. B. via a radio link or via the string lines, z. B. by means of so-called PowerLine Communication.

Preferably, the control means comprises a safety device, which for the activation of the protection circuit from the protection state to the operating state, an authorization, for. B. requires a code entry. Not only does this provide protection against unauthorized personnel switching to operation, it also provides inherent theft protection because the solar panel can not be unlocked without the authorization code of a thief without removing the junction box.

Nevertheless, in the junction box also a conventional Theft protection device be installed. Furthermore, if necessary, a maximum powerpoint tracking control device, a voltage monitoring device, a current monitoring device and / or a temperature monitoring device are installed in the junction box, which are connected from the poles of the solar panel in front of the disconnector and the short circuit switch. Thus, the theft protection device, the maximum powerpoint tracking controller, the voltage monitoring device, the current monitoring device or the temperature monitoring device can also be supplied with electrical power in the protective state of the solar panel.

Accordingly, the invention also relates to an electrical protection circuit for installation in a junction box for a solar panel, by means of which the live conductor strips of the positive pole and the negative pole of the solar panel on the one hand and the strand lines on the other connected and electrically connected to each other,
wherein the protection circuit defines an operating state in which the electrical power of the solar panel is dissipated via the first and second external connection lines and a protection state in which the associated solar panel is disconnected from the external connection lines,
wherein a control device is included for controlling the protection circuit,
wherein the protection state is an idle state in which the protection circuit is self-energized and remains there until the protection circuit is reactivated by an activation intervention by the control device and
wherein the control device is supplied in the protective state of the associated solar panel with electrical power when the protection circuit is installed in the junction box on a solar panel to enable the protection circuit from the protection state to the operating state can.

To supply and build a solar generator, the solar panels are each manufacturer side equipped with a junction box with integrated protection circuit and in the protective state to the construction site, eg. B. a building roof, delivered. At the construction site, the solar panels are installed and wired to the strand cables. Subsequently, the solar generator is subjected to standard commissioning tests, eg. B. after DIN VDE 0100-600, DIN VDE 0100-600: 2008-06 . IEC 60364-6: 2006 / HD 60364-6: 2007 and or DIN EN 62446 VDE 0126-23: 2010-07 , Only after the installation and commissioning tests of the solar generator, the protective circuits of the solar panels are switched from the protection state to the operating state and thus put the wiring under electrical power. This ensures a particularly high level of safety during transport, storage and installation of the solar panels or the solar generator.

If the activation of the protection circuit from the protection state to the operating state by the control device, an authorization, for. B. requires a code input, can also be ensured that the individually possible activation or activation of the solar panels can be made only by special authorized for the acceptance personnel. As long as no authorized activation has taken place, the solar generator remains free of power beyond the junction box, viewed from the solar panels.

Switching from the operating state to the protection state, d. H. the activation of the solar panel of the strand lines can z. B. for maintenance and in case of failure under exposure. For maintenance, it is particularly advantageous that the solar panels can be individually unlocked. When disconnecting, it is preferred to first close the short-circuit switch in the respective protection circuit in order to short-circuit the output-side connection elements of the first and second external connection line and thus to generate a bypass for the respective solar panel in the line and only in a subsequent second step the circuit breaker to open and thus to disconnect the already closed short circuit switch at least from one pole of the solar panel.

In the following the invention will be explained in more detail by means of embodiments and with reference to the figures, wherein the same and similar elements are partially provided with the same reference numerals and the features of the various embodiments can be combined.

Brief description of the figures

Show it:

1 a perspective view of a junction box for a solar panel,

2 a perspective view of a stack of solar panels with mounted junction box,

3 a schematic representation with circuit diagram of a first embodiment of the invention in the operating state,

4 the embodiment of 3 in the protective state,

5 a further embodiment of the invention in the operating state,

6 the embodiment of 5 in the protective state,

7 a further embodiment of the invention in the protective state.

Detailed description of the invention

1 shows a junction box 12 with a junction box 14 for mounting on the back of a solar panel. The dielectric junction box 14 is hat-shaped and has circumferential side walls 14a to 14d as well as a lid 14e on. At the in 1 Unseen underside of the junction box 14 There are openings through which the conductor strip emerging from the solar module into the junction box 12 to join or be contacted. The junction box 14 points to one of the side walls 14a a first and second cable gland 16a . 16b on, through which the strand lines 18a respectively. 18b in the junction box 12 guided and inside the junction box 14 z. B. are connected by means not shown contact terminals to dissipate the electrical power generated by the solar panel. For the basic mechanical structure of a junction box for a solar panel z. B. on the DE 10 2007 037 130 and the DE 10 2007 042 547 directed.

2 shows 16 on a pallet 22 stacked solar panels 24 , The solar panel lying to Colonel 24 lies with his back 24a up and on the back 24a is the junction box 12 with prefabricated strand cables 18a and 18b glued. For this purpose, the junction box 14 at its bottom 14f a circumferential adhesive edge 14g on.

The solar panel 24 has a surrounding aluminum frame 24b , which forms a depression on the back of the solar panel, so that the glued junction box 12 is relatively well protected mechanically. 2 shows a typical condition in which solar panels are shipped.

3 shows a schematic representation of the solar panel 24 with a variety of solar cells. The entirety of the photovoltaic solar cells is marked with the symbol 26 represents. From the solar module occur two conductor bands 28a . 28b out, which form the positive pole or the negative pole of the solar module. The leader ribbons 28a and 28b protrude from below into the junction box 12 in and are in the junction box 12 with input-side connection elements 32a respectively. 32b connected and contacted. Examples of corresponding connection elements in the form of contact terminals can be found in the DE 10 2007 037 130 and the DE 10 2007 042 547 , In the junction box 12 is also a bypass diode 34 parallel to the solar cells 26 connected.

The junction box 12 houses a protection circuit 40 with a short-circuit switch 42 , which is parallel to the solar cells 26 and the bypass diode 34 is switched. The short-circuit switch 42 is directly on the output side connection elements 36a and 36b arranged and can short-circuit them. At the output side connection elements 36a . 36b are the strand cables 18a respectively. 18b connected. This can be z. B. by means of contact terminals, but it is also possible, the junction box 12 or the junction box 14 equip directly with connectors.

The protection circuit 40 also includes an unlock switch 44 , the serial between the short-circuit switch 42 and one of the two input-side connection elements is connected, in this example, the input-side connection element 32a the plus pole of the solar cells 26 , The short-circuit switch 42 and the unlocker 44 are from a controller or a controller 46 controlled. The respective control is with the dashed lines 43 . 45 which z. B. control lines represent symbolizes. The control device 46 is via utility lines 48 from the solar cells 26 the associated solar panel supplied with electrical power. The supply lines 48 are seen from the solar panel before the breaker 44 connected. 3 shows the protection circuit 40 in the operating state, ie the short-circuit switch 42 is open and the breaker 44 is closed, so that the solar cells 26 this solar panel 24 with the string lines 18a . 18b are connected and via the string lines 18a . 18b the electrical power of this solar panel can be fed.

4 shows the solar panel 24 out 3 , where the protection circuit 40 is switched to the protection state. In the protection state is the short-circuit switch 42 closed and thus closes the output-side connection elements 36a and 36b short with each other, so based on the strand lines 18a and 18b this solar panel 24 low impedance is bypassed. The remaining solar panels can continue to generate electrical power and feed into the grid, as the circuit of the string lines 18a . 18b over the closed short-circuit switch 42 closed is. It is only the strand stress due to the lack of this solar panel 24 reduced.

The serial disconnector 44 is open in the illustrated protection state, so that the Short-circuit switch 42 although it is closed, not the solar cells 26 this solar panel 24 shorts. Thus, the solar cells generate 26 this solar panel 24 No power dissipation in the closed short-circuit switch 42 , Furthermore, the bypass diode remains 34 with the solar cells 26 connected. In addition, the control device 46 also in the illustrated protective state of the solar cells 26 further supplied with electrical power.

In the 5 illustrated embodiment of the solar panel 24 indicates one in three groups of solar cells 26a . 26b . 26c split solar module on. The groups of solar cells 26a . 26b . 26c typically again consist of a plurality of individual solar cells, which may be connected inside the groups serially and / or in parallel module-internal. It is only important that between the groups 26a . 26b . 26c Intermediate taps in the form of additional conductor strips 28c and 28d are provided. These are with other input-side connection elements 32c . 32d connected and contacted within the junction box. With the intermediate taps so the subgroups of the solar cells 26a . 26b . 26c in a solar module 24 own bypass diodes 34a . 34b . 34c be assigned to the effect that each of the separately led out and connected groups of solar cells 26a . 26b . 26c one bypass diode each 34a . 34b . 34c is connected in parallel.

Furthermore, the control device comprises 46 an electronic functional element module 52 , z. B. a power, voltage and / or temperature monitoring device or a theft protection device MPPT control device or the like. As the control device 46 in front of the short-circuit switch 42 and the unlocker 44 connected to the two poles of the solar panel is also the functional element assembly 52 both in the operating state and in the protective state of the solar cells 26a . 26b . 26c this solar panel 24 supplied with electrical power.

Furthermore, the control device 46 a safety device 54 which requires a code input to the shorting switch 42 to open and the unlocker 44 to close, that is, the protection circuit 40 switch from the protection state to the operating state. The control device 46 also has a radio device 56 auf, receives the corresponding radio signals from a central control device, not shown, so that each solar panel 24 centrally controlled by authorized personnel, in particular can be switched to the operating state.

In this embodiment, the string current is connected to a current sensor 58 monitored in the junction box. The current sensor 58 is between one of the two output-side connection elements 36a . 36b and the associated port 42a respectively. 42b of the short-circuit switch 42 switched to the junction box 12 to be able to measure the phase current both in the operating state and in the protective state. In the operating state, the current flows through the solar cells 26a . 26b . 26c of the associated solar panel 24 and in the protection state via the closed short-circuit switch 42 , In other words, the current sensor 58 relative to the to the external connection elements 36a . 36b connected external connection cables 18a . 18b (Line) serial to the short-circuit switch 42 connected. Through this (string) current monitoring in the junction box 12 there is the possibility of the protection circuit 40 to activate or deactivate in response to the measured current level. If z. B. the string line 18a . 18b is de-energized, z. B. because the DC disconnect switch is turned off before the inverter, the protection circuit switches 40 in response to the current interruption measured in the junction box automatically in the protective state. The protection circuit can later by an initial current through the strand, z. B. from the generator junction box, the protection state are switched back to the operating state, since the strand line is uninterruptible, although some or even all protection circuits are in the protective state.

6 shows the embodiment 5 in the state of protection. According to the preferred embodiment, the shorting switch 42 as normally closed or normally closed contact and the disconnector 44 designed as a make or normally open contact. Will the power supply to the controller 46 from the associated solar panel 24 interrupted, z. B. by a contact problem on one of the input-side connection elements 32a . 32b or if the controller 46 is defective, the protection circuit drops 40 automatically in the protection state, ie the short-circuit switch falls into the closed position and the circuit breaker in the open position. The protection circuit then remains in the protection state until an active control intervention by the control device 46 takes place, which the protection circuit 40 activated again in the operating state, ie the short-circuit switch 42 opens and unlocks 44 closes. This can be z. B. with appropriate relay or self-locking or self-conducting MOS-FETs can be realized.

Referring to 7 shows a further modification of the invention is shown in which the protection circuit is still a second circuit breaker 44 ' which serially between the negative pole of the solar cells 26 and the short-circuit switch 42 is switched. This allows both ports 42a and 42b of the short-circuit switch, if necessary galvanically from the solar cells 26 be separated. In contrast, the protection circuit according to 3 to 6 only from the short-circuit switch 42 , Unlocker 44 and the controller 46 to control the two switches 42 . 44 ,

For maintenance, any solar panel 24 with the protection circuit according to the invention 40 individually from the strand 18a . 18b be switched off, without the functioning of the other solar panels in the strand 18a . 18b to influence (except that the strand tension decreases) and still can in the junction box 12 of the switched off solar panel 24 existing electronics 46 . 52 . 54 . 56 from the solar cells 26a . 26b . 26c this solar panel 24 continue to be supplied with electrical power. In particular, the control device 46 is also in the protective state of the solar cells 26a . 26b . 26c still supplied with electrical power and is thus enabled, the switching operations of the switches 42 and 44 from the protection state to the operating state.

It will be apparent to those skilled in the art that the above-described embodiments are to be read by way of example, and that the invention is not limited thereto, but that it can be varied in many ways without departing from the scope of the claims. Furthermore, regardless of whether they are disclosed in the specification, the claims, the figures, or otherwise, the features also individually define essential components of the invention, even if e.g. B. are described together in the embodiments together with other features.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102007037130 [0004, 0044, 0047]
• DE 102007042547 [0004, 0044, 0047]
• DE 102009024516 A1 [0008]

Cited non-patent literature

• DIN VDE 0100-600, DIN VDE 0100-600: 2008-06 [0032]
• IEC 60364-6: 2006 / HD 60364-6: 2007 [0032]
• DIN EN 62446 VDE 0126-23: 2010-07 [0032]

Claims (20)

Junction box ( 12 ) for a solar panel ( 24 ) for the electrical connection of external connecting cables ( 18a . 18b ) to a solar panel, the junction box ( 12 ) includes: one on the solar panel ( 24 ) mountable junction box ( 14 ), input-side connection elements ( 32a . 32b ) for connecting the live conductors ( 28a . 28b ) of the positive pole and the negative pole of the solar panel ( 12 ), output-side connecting elements ( 36a . 36b ) for connecting a first and second external connection line ( 18a . 18b ) to the junction box ( 12 ), a protection circuit ( 40 ), which defines an operating state and a protective state, wherein in the operating state the first external connecting line ( 18a ) with the live conductor ( 28a ) of the positive pole of the solar panel and the second external connecting line ( 18b ) with the live conductor ( 28b ) of the negative pole of the solar panel are electrically connected, so that the electrical power generated by the solar panel via the first and second external connecting line ( 18a . 18b ) is discharged, wherein the protective circuit ( 40 ) a short-circuit switch ( 42 ) between the output-side connecting elements ( 36a . 36b ) of the first and second external connection lines ( 18a . 18b ) and an unlock switch ( 44 ), wherein in the protection state the short circuit switch ( 42 ) the output-side connecting elements ( 36a . 36b ) of the first and second external connection lines ( 18a . 18b ) and the circuit breaker ( 44 ) the short circuit switch ( 42 ) separates at least on one side of the solar panel. Junction box ( 12 ) for a solar panel ( 24 ) according to claim 1, wherein the short circuit switch ( 42 ) in the junction box from the poles ( 28a . 28b ) of the solar panel directly in front of the output-side connection elements ( 36a . 36b ) of the first and second external connection lines ( 18a . 18b ) and the circuit breaker ( 44 ) in the junction box ( 12 ) serially between the input-side connection element ( 32a ) of the live conductor ( 28a ) of the positive pole of the solar panel or the input-side connection element ( 32b ) of the live conductor ( 28b ) of the negative pole of the solar panel and the associated connection of the short-circuit switch ( 42 ) is switched. Junction box ( 12 ) for a solar panel according to claim 1 or 2, wherein the junction box at least one bypass circuit ( 34 ) to compensate for shadowing and the breaker ( 44 ) in series with the at least one bypass circuit ( 34 ) to compensate shading and / or the short-circuit switch ( 42 ) parallel to the at least one bypass circuit ( 34 ) is switched to compensate shading. Junction box ( 12 ) for a solar panel according to claim 3, wherein the at least one bypass circuit ( 34 ) to compensate for shadowing of the poles ( 28a . 28b ) of the solar panel as seen in front of the circuit breakers ( 44 ) and the short-circuit switch ( 42 ), so that the at least one bypass circuit ( 34 ) remains in the protective state connected to the solar panel to compensate for shadowing. Junction box ( 12 ) for a solar panel ( 24 ) according to one of the preceding claims, for a group of solar cells ( 26a . 26b . 26c ) divided solar panel ( 24 ) with electrical intermediate taps between the groups, comprising further input-side connection elements ( 32c . 32d ) for connecting the live conductors ( 28c . 28d ) of the intermediate taps, and a plurality of bypass circuits ( 34a . 34b . 34c ) for compensation of shadowing, which in each case parallel to the associated groups of solar cells ( 26a . 26b . 26c ) are connected when the junction box ( 12 ) on the solar panel ( 24 ), whereby the short circuit switch ( 42 ) parallel to the bypass circuits ( 34a . 34b . 34c ) for the compensation of shadowing and the groups of solar cells ( 26a . 26b . 26c ), when the junction box ( 12 ) on the solar panel ( 24 ) and wherein the release switch ( 44 ) in series between the short-circuit switches ( 42 ) and the bypass circuits ( 26a . 26b . 26c ) for the compensation of shadowing and the groups of solar cells ( 26a . 26b . 26c ), when the junction box ( 12 ) on the solar panel ( 24 ) is mounted in the protective state, the short-circuit switch ( 42 ) by means of the release switch ( 44 ) from all groups of solar cells and bypass circuits to compensate for shadowing. Junction box ( 12 ) for a solar panel ( 24 ) according to one of the preceding claims, wherein the short circuit switch ( 42 ) and the breaker ( 44 ) in the junction box ( 14 ) from the poles ( 28a . 28b ) of the solar panel are installed before any lying outside the junction box releasable connectors. Junction box ( 12 ) for a solar panel ( 24 ) according to one of the preceding claims, comprising a control device ( 46 ) switching the protection circuit ( 40 ) from the protection state to the operating state, wherein the control device ( 46 ) is supplied in the protective state of the associated solar panel with electrical energy. Junction box ( 12 ) for a solar panel ( 24 ) according to one of the preceding claims, wherein the short circuit switch ( 42 ) and / or the circuit breaker ( 44 ) comprise a mechanical switch, an electromechanical switch or a semiconductor switch. Junction box ( 12 ) for a solar panel ( 24 ) according to one of the preceding claims, wherein the short circuit switch ( 42 ) is designed as an opener and is closed when at rest. Junction box ( 12 ) for a solar panel ( 24 ) according to one of the preceding claims, wherein the release switch ( 44 ) is designed as a closer and is open at rest. Junction box ( 12 ) for a solar panel ( 24 ) according to claim 9 or 10, wherein in the protective state the short-circuiting switch ( 42 ) and the breaker ( 44 ) are at rest and from the respective idle state by means of the control device ( 46 ) in response to the activation of the protection circuit ( 40 ) from the idle protection state to the operating state. Junction box ( 12 ) for a solar panel ( 24 ) according to claim 11, wherein the activation of the protection circuit ( 40 ) from the protective state to the operating state remotely controlled from outside the junction box ( 12 ) he follows. Junction box ( 12 ) for a solar panel ( 24 ) according to claim 11 or 12, wherein the control device ( 46 ) a safety device ( 54 ), which are used for the activation of the protective circuit ( 40 ) requires an authorization from the protection state to the operating state. Junction box ( 12 ) for a solar panel ( 24 ) according to one of the preceding claims, wherein in the junction box ( 12 ) at least one theft protection device, a maximum powerpoint tracking control device, a voltage monitoring device, a current monitoring device and / or a temperature monitoring device are installed, which of the poles ( 28a . 28b ) of the solar panel as seen in front of the circuit breakers ( 44 ) and the short-circuit switch ( 42 ) and the theft prevention device, the maximum powerpoint tracking control device, the voltage monitoring device, the current monitoring device or the temperature monitoring device are also supplied with electrical power in the protective state of the solar panel. Junction box ( 12 ) according to any one of the preceding claims, further comprising a current sensor ( 58 ), between one of the external connection lines ( 18a . 18b ) and the short-circuit switch ( 42 ), so that in the protective state of the through the external connecting lines ( 18a . 18b ) flowing current can be measured. Protection circuit ( 40 ) for installation in a junction box ( 12 ) for a solar panel ( 24 ), by means of which the live conductors ( 28a . 28b ) of the positive pole and the negative pole of the solar panel and the first and second external connecting line ( 18a . 18b ) are electrically connected in a solar generator to the solar panel, in particular according to one of the preceding claims, wherein the protective circuit ( 40 ) an operating state in which the electrical power of the solar panel via the first and second external connection line ( 18a . 18b ) and a protection state, in which the external connection lines are switched off in relation to the associated solar panel, defined, wherein a control device ( 46 ) for controlling the protection circuit ( 40 ), wherein the protection state is an idle state, in which the protection circuit ( 40 ) falls automatically in the absence of power and remains there until the protection circuit ( 40 ) from the control device ( 46 ) is activated again and wherein the control device ( 46 ) is supplied with electrical power in the protective state of the associated solar panel, when the protection circuit ( 40 ) in the junction box ( 12 ) on a solar panel ( 29 ) is installed to protect the protective circuit ( 40 ) to be able to activate from the protection state into the operating state. Method for supplying and constructing a solar generator, wherein a plurality of solar panels ( 24 ) each with a junction box ( 12 ) with integrated protection circuit ( 40 ) according to any one of the preceding claims in the protective state to the building site manufacturer, the solar panels ( 24 ) are installed at the installation site and connected to the external connecting cables ( 18a . 18b ) and the solar generator is subjected to the standard commissioning tests and the protective circuits ( 40 ) of the solar panels ( 24 ) are transferred from the protection state to the operating state only after installation and after commissioning checks of the solar generator. The method of claim 17, wherein activating the protection circuit ( 40 ) from the protection state to the operating state by the control device ( 46 ) requires authorization. Method for activating one or more solar panels ( 24 ) each with a junction box ( 12 ) according to one of the claims 1 to 15, in an installed and under exposure stationary and voltage-generating solar generator for maintenance or in the event of a fault, in particular in the case of a fire, wherein the solar panel or panels ( 24 ) individually from the remaining solar panels ( 24 ) of the solar generator, in which in the associated protection circuit ( 40 ) in each case in a first step, first the short-circuit switch ( 42 ) is closed to the output-side connection elements ( 38a . 38b ) of the first and second external connection lines ( 18a . 18b ) and in a subsequent second step the circuit breakers ( 44 ) and the already closed short-circuit switch ( 42 ) at least one pole ( 28a . 28b ) of the solar panel. The method of claim 19, wherein in each case at the solar panels with a to the junction box ( 12 ) associated current sensor ( 58 ) through the external connection lines ( 18a . 18b ) flowing current is measured and the protection circuit ( 40 ) switches to the protection state or the operating state in response to the measured current.

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